Construction of 3D interconnected diamond networks in Al-matrix composite for high-efficiency thermal management

[Display omitted] •3D interconnected diamond networks with high quality was fabricated.•Al-matrix composite incorporated with diamond networks were synthesized.•The diamond networks kept good integrity and high quality as efficient channels for heat transfer.•Significant thermal conductivity enhance...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2020-01, Vol.380, p.122551, Article 122551
Main Authors: Zhang, Long, Wei, Qiuping, An, Junjie, Ma, Li, Zhou, Kechao, Ye, Wentao, Yu, Zhiming, Gan, Xueping, Lin, Cheng-Te, Luo, Jingting
Format: Article
Language:English
Subjects:
3D interconnected
Al-matrix composite
CVD
Diamond networks
High-efficiency thermal management
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Summary:[Display omitted] •3D interconnected diamond networks with high quality was fabricated.•Al-matrix composite incorporated with diamond networks were synthesized.•The diamond networks kept good integrity and high quality as efficient channels for heat transfer.•Significant thermal conductivity enhancement was achieved at a low diamond loading. Realizing high-efficiency thermal management is of great significance for the fast growth of high-performance electronic devices. Herein, three-dimensional (3D) diamond networks (DN) are proposed as highly thermal conductive reinforcements for Al-matrix composite by template-directed chemical vapor deposition (CVD) on Cr-modified Cu foams. The diamond networks with dense and uniform structure were further incorporated with pure Al by gas pressure infiltration (GPI). Results showed that the diamond skeletons were uniformly and integrally distributed in the dense Al matrix with a compact interfacial bonding and limited interface product after GPI process. A relatively high thermal conductivity of 315.7 W/mK was achieved at a low diamond loading of 4.6 vol.%, which was equivalent to 54% enhancement compared to pure Al. The synthesized diamond networks with high quality and continuous structure can act as high-efficiency heat transfer pathways to ensure most of heat being transferred through the 3D diamond skeletons, which effectively reduced the phonon-boundary scatterings. As a consequence, the fabricated composite shows a great superiority in both thermal conductivity and thermal conductivity enhancement efficiency as compared with the conventional Al-matrix composites reinforced with even higher volume fraction of diamond particles. The construction of 3D interconnected diamond networks in metal-matrix composites might open new doors for the design and preparation of high-efficiency thermal management materials.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2019.122551